A Novel Method for the Simultaneous Enrichment,Identification, and Quantification of Phosphopeptides and Sialylated Glycopeptides Applied to a Temporal Profile of Mouse Brain Development

We describe a method that combines an optimized titanium dioxide protocol and hydrophilic interaction liquid chromatography to simultaneously enrich, identify and quantify phosphopeptides and formerly N-linked sialylated glycopeptides to monitor changes associated with cell signaling during mouse brain development. We initially applied the method to enriched membrane fractions from HeLa cells, which allowed the identification of 4468 unique phosphopeptides and 1809 formerly N-linked sialylated glycopeptides. We subsequently combined the method with isobaric tagging for relative quantification to compare changes in phosphopeptide and formerly N-linked sialylated glycopeptide abundance in the developing mouse brain. A total of 7682 unique phosphopeptide sequences and 3246 unique formerly sialylated glycopeptides were identified. Moreover 669 phosphopeptides and 300 formerly N-sialylated glycopeptides differentially regulated during mouse brain development were detected. This strategy allowed us to reveal extensive changes in post-translational modifications from postnatal mice from day 0 until maturity at day 80. The results of this study confirm the role of sialylation in organ development and provide the first extensive global view of dynamic changes between N-linked sialylation and phosphorylation.The development of novel methods to simultaneously monitor multiple protein post-translational modifications (PTMs)¹ is an attractive tool for researchers. There is increasing evidence that both phosphorylation and glycosylation play important roles in cellular signaling networks during development and transformation of cells. Development of the mammalian brain is initiated during the embryonic stage and continues until adulthood. The brain originates through the proliferation of the telencephalon, the anterior part of the neural tube. Following differentiation, cells begin to migrate and associate into different brain structures. The brain structures are reorganized with the extension of axons and dendrites to communicate via synaptic terminal interactions (1, 2). These molecular interactions are governed by cell surface receptors that are often post-translationally modified with both N-linked glycans and phosphate groups, and studies have suggested that extracellular glycans play vital roles in the regulation of signal transduction pathways (3). For example, the myelin-associated glycoprotein (MAG) binds to cell surface glyco-conjugates GD1a, GT1b and Nogo receptors to form signaling complexes that inhibit axon outgrowth, whereas inhibition of Rho kinase reverses this process in a number of nerve cell types (4). There is growing evidence that both the differentiation and migration of neurons and the guidance of axons are regulated by sialic acid-containing glycoconjugates (5–7). Dietary supplementation of sialic acid leads to increases in sialic acid-containing glycoproteins in the frontal cortex and is associated with faster learning and memory in piglets (8). The nervous system contains an abundant array of sialylated molecules and it is therefore not surprising that changes in the sialiome (the content of sialylated glycoproteins (9)) of a neuron can regulate activity. Removal of sialic acids from membrane proteins by NEU3 in primary neurons leads to actin depolymerization and axonal growth through TrkA-mediated signaling (10). Moreover, the modulation of phosphorylation events because of changes in cell membrane sialylation has been described in cancer (11, 12). Tumors induced in sialyltransferase-deficient animals show altered expression of genes associated with focal adhesion signaling and display decreased phosphorylation of focal adhesion kinase, a target of β1-integrins (13). Sialylated glycoconjugates include N-linked glycans (attached to asparagine residues), O-linked glycans (attached to hydroxylated residues) and glycolipids. N-linked and O-linked glycans are predominantly processed through the endoplasmic reticulum and Golgi, and their protein targets are generally membrane associated, cell-surface or found in extracellular environments. Additional glycoconjugates include single sugar modifications such as O-linked N-acetylglucosamine, glycosaminoglycans, large lipopolysaccharides, and peptidoglycans.The ability to identify and quantify PTM in proteins using mass spectrometry (MS) relies on specific enrichment techniques to purify modified peptides-of-interest from among a complex mixture. As modified peptides are normally present in sub-stoichiometric levels compared with nonmodified peptides, they are generally not detected by MS without such specific enrichment. Many methods are available to enrich for single PTM, including phosphorylation and glycosylation. Titanium dioxide (TiO₂) chromatography was originally described for enrichment of phophopeptides from peptide mixtures using similar peptide loading conditions as used for immobilized metal affinity chromatography (14–16). However, using this procedure resulted in significant co-enrichment of nonphosphorylated peptides. Later we demonstrated that TiO₂ was able to selectively purify phosphorylated peptides and sialic acid-containing N-glycopeptides (9, 17) if peptide samples are loaded onto the TiO₂ resin in a buffer containing high organic solvent, very low pH and a multifunctional acid, such as 2,5- dihydroxybenzoic acid or glycolic acid.A recent study demonstrated the first simultaneous enrichment of N-glycopeptides and phosphopeptides from a complex peptide mixture (18). Peptides from mouse brain were separated using electrostatic repulsion hydrophilic interaction chromatography to identify 738 unique glycosylation sites representing 446 glycoproteins, and 915 unique phosphorylation sites from 382 phosphoproteins. This method however, required 3 mg of starting material and did not demonstrate the ability to selectively enrich sialylated glycopeptides from glycopeptides displaying neutral glycans. Furthermore, only a comparatively low number of phosphopeptides could be identified considering the generous protein load investigated. The method was also unable to separate deglycosylated peptides from phosphopeptides and no quantitative capabilities were shown.Here we report a novel multidimensional strategy that employs TiO₂ chromatography to enrich for sialylated glycopeptides and phosphopeptides followed by PNGase F treatment of the eluent and μHPLC hydrophilic interaction liquid chromatography (HILIC) to fractionate and separate formerly N-linked sialylated glycopeptides and phosphopeptides from complex membrane protein preparations of a variety of biological samples. The development of a quantitative N-linked sialiomics and phosphoproteomic strategy that is able to simultaneously monitor cell-(extracellular)-cell interactions and receptor signaling will be a valuable tool to study tissue development and cell stimulation.